A FinFET includes a semiconductor layer having a fin structure that protrudes out of the semiconductor layer. The fin structure includes a first segment and a second segment disposed over the first segment. A dielectric layer is disposed over the semiconductor layer. The first segment of the fin structure is surrounded by the dielectric layer. A metal layer is disposed over the dielectric layer. The second segment of the fin structure is surrounded by the metal layer. The dielectric layer has a greater nitrogen content than the metal layer. The first segment of the fin structure also has a first side surface that is rougher than a second side surface of the second segment of the fin structure.

A multilayer composite structure and a method of preparing a multilayer composite structure are provided. The multilayer composite structure comprises a semiconductor handle substrate having a minimum bulk region resistivity of at least about 500 ohm-cm and an isolation region that impedes the transfer of charge carriers along the surface of the handle substrate and reduces parasitic coupling between RF devices.

A semiconductor device having a super junction and a method of manufacturing the semiconductor device capable of obtaining a high breakdown voltage are provided, whereby charge balance of the super junction is further accurately controlled in the semiconductor device that is implemented by an N-type pillar and a P-type pillar. The semiconductor device includes a semiconductor substrate; and a blocking layer including a first conductive type pillar and a second conductive type pillar that extend in a vertical direction on the semiconductor substrate and that are alternately arrayed in a horizontal direction, wherein, in the blocking layer, a density profile of a first conductive type dopant may be uniform in the horizontal direction, and the density profile of the first conductive type dopant may vary in the vertical direction.

A periodic table Group 13 metal nitride crystals grown with a non-polar or semi-polar principal surface have numerous stacking faults. The purpose of the present invention is to provide a period table Group 13 metal nitride crystal wherein the occurrence of stacking faults of this kind are suppressed. The present invention achieves the foregoing by a periodic table Group 13 metal nitride crystal being characterized in that, in a Qx direction intensity profile that includes a maximum intensity and is derived from an isointensity contour plot obtained by x-ray reciprocal lattice mapping of (100) plane of the periodic table Group 13 metal nitride crystal, a Qx width at 1/300th of peak intensity is 6×10.sup.−4 rlu or less.

According to one embodiment, a semiconductor memory device includes a semiconductor substrate, a stacked body, a semiconductor member, a semiconductor portion, a first insulating film, and a charge storage film. The semiconductor member includes a first portion and a second portion, the first portion contacting with the semiconductor substrate, the second portion being provided on the first portion, contacting with the first portion, and having a second width smaller than a first width of the first portion in a first direction crossing a stacking direction. The first insulating film is provided on a side surface of the second portion. The charge storage film is provided on a side surface of the semiconductor portion, extends in the stacking direction, and includes a first portion located on an upper surface of the second portion of the semiconductor member.

Provided is a manufacturing device capable of effectively and sufficiently reducing an edge crown. The wafer support is used in a chemical vapor phase growth device in which an epitaxial film is grown on a main surface of a wafer using a chemical vapor deposition method, the wafer support including: a wafer mounting surface having an upper surface on which a substrate is mounted; and a wafer support portion that rises to surround a wafer to he mounted, in which a height from an apex of the wafer support portion to a main surface of the wafer mounted on the wafer mounting surface is 1 mm or more.

A method for growing semiconductor wafers by lateral diffusion liquid phase epitaxy is described. Also provided are a refractory device for practicing the disclosed method and semiconductor wafers prepared by the disclosed method and device. The disclosed method and device allow for significant cost and material waste savings over current semiconductor production technologies.

In various embodiments, a method is provided. The method may include forming a buried electrically charged region at a predefined position in a first layer in such a way that the buried electrically charged region generates an electric field having a lateral inhomogeneous field distribution above the first layer, and forming a second layer above the first layer using the field distribution in such a way that a structure of the second layer correlates with the position of the buried electrically charged region.

Described herein are techniques for forming an epitaxial III-V layer on a substrate. In a pre-clean chamber, a native oxygen layer may be replaced with a passivation layer by treating the substrate with a hydrogen plasma (or products of a plasma decomposition). In a deposition chamber, the temperature of the substrate may be elevated to a temperature less than 700° C. While the substrate temperature is elevated, a group V precursor may be flowed into the deposition chamber in order to transform the hydrogen terminated (Si—H) surface of the passivation layer into an Arsenic terminated (Si—As) surface. After the substrate has been cooled, a group III precursor and the group V precursor may be flowed in order to form a nucleation layer. Finally, at an elevated temperature, the group III precursor and group V precursor may be flowed in order to form a bulk III-V layer.

A gallium nitride based semiconductor device is provided, where when a thickness of a transition layer is defined as the followings, the thickness of the transition layer is less than 1.5 nm: (i) a distance between a depth position at which an atomic composition of nitrogen element constituting the gallium nitride based semiconductor layer is ½ relative to that at a position on the GaN based semiconductor layer side sufficiently away from the transition layer, and a depth position at which an atomic composition of a metal element is ½ of a value of a maximum if an atomic composition of the metal element constituting an insulating layer has the maximum, or a depth position at which an atomic composition of the metal element is ½ relative to that at a position on the insulating layer side sufficiently away from the transition layer if not having the maximum.